Continuous Time Analogue/Digital Converter

ABSTRACT

Continuous time analogue/digital converter, comprising a sigma delta modulator (MSD 1 ) configured to receive an analogue input signal (x(t)) and comprising high-pass filtering means (MF) the chopping frequency of which is equal to half of the sampling frequency (Fs) of the quantization means (QTZ) of the modulator (MSD 1 ).

This application is a continuation of U.S. patent application Ser. No. 13/024,729, filed on Feb. 10, 2011, and entitled “Continuous Time Analogue/Digital Converter,” which application further claims the benefit of French Patent Application No. FR 10-51011, filed on Feb. 15, 2010, and entitled “Continuous Time Analogue/Digital Converter,” which applications are hereby incorporated herein by reference to the maximum extent allowable by law.

TECHNICAL FIELD

The invention relates to the continuous-time conversion of analogue signals to digital signals and applies advantageously but not limitingly to the radio-frequency field, for example in mobile telephony, in which the radiofrequency circuits mostly use analogue/digital conversion devices both in transmission and reception.

BACKGROUND

These conversion devices are usually produced within integrated circuits. They may be continuous time (or CT according to the term commonly used by those skilled in the art) or else discrete time (or DT according to the term commonly used by those skilled in the art).

Usually, this conversion is carried out with the aid of a sigma delta modulator because it provides a good resolution of conversion and rejects quantization noise outside the payload band of the signal.

FIG. 1 illustrates schematically an example of a structure usually used for sigma delta modulators within a continuous time converter CT. The structure of sigma delta modulators is usually based on the combination of an integrator and a summer, the assembly being looped. The diagram of a sigma delta modulator is therefore that of a closed-loop control system.

The sigma delta modulator MSD comprises at the head a summer SOM (subtractor) receiving an analogue input signal x(t) having a frequency Fe. This subtractor is in this instance followed by an integrator INT the output of which is connected to the input of a quantization means QTZ (sampler) the output of which forms the output of the modulator. The output of the quantization means QTZ is looped back to the negative input of the summer SOM by means of a digital/analogue converter DAC. The quantization means QTZ converts the signal from the integrator INT into a digital signal y(n). Moreover, the modulator MSD comprises a clock generator CLK in order to generate a sampling frequency Fs intended for the quantization means QTZ and for the converter DAC.

The “delta” modulation is based on the quantization of the modification of the analogue input signal x(t). The presence of a “sigma” integrator in the modulator gives the modulator the title of “sigma delta” modulator. The integrator usually comprises a low-pass filter

This being so, there are also bandpass sigma delta modulators which comprise, instead of an integrator, a bandpass filter. These modulators, although they have no integrator, still retain, the title “sigma delta modulator”.

In practice, in radio-frequency applications, use is made of a bandpass filter and a sampling frequency Fs which is approximately equal to four times the frequency of the analogue input signal x(t). Since the sampling frequency is very high, this modulator MSD does not make it possible to convert high-frequency analogue signals; usually the frequency of the input signals is limited to a few gigahertz.

Moreover, as indicated above, in order to convert the analogue signals, it is also possible to use a discrete time analogue/digital converter DT. These converters also use sigma delta modulators but unlike the continuous-time use described above, these modulators receive a sampled signal as an input. These converters also comprise a first frequency mixer situated upstream of the modulator in order on the one hand to sample the analogue input signal and on the other hand to transpose the frequency of the input signal around a carrier frequency. Then the modulator converts the sampled signal received into a digital output signal. This converter also comprises a second mixer situated at the output of the modulator in order to again transpose the frequency of the digital output signal around the frequency of the input signal.

Sampling the analogue input signal makes it possible to use a sampling frequency value for the sigma delta modulator that is lower than that used in the continuous time converter CT described above. Specifically, for a discrete time converter DT, the sampling frequency is approximately equal to twice the frequency of the analogue input signal.

These discrete time converters DT do not make it possible to convert the analogue signals at frequencies higher than the continuous time converters CT. Moreover, they have a complex architecture because they use two frequency mixers.

SUMMARY OF THE INVENTION

In one aspect, the present invention provides for a continuous time analogue/digital converter. The converter includes a sigma delta modulator configured to receive an analogue input signal. The modulator includes a quantization means having a sampling frequency; and a high-pass filtering means having a chopping frequency that is equal to half of the sampling frequency of the quantization means.

In another aspect, the present invention provides for a wireless communication device having a sigma delta modulator configured to receive an analogue input signal. The modulator includes a quantization means having a sampling frequency, and a high-pass filter having a chopping frequency that is equal to half of the sampling frequency of the quantization means.

In yet another aspect, the present invention provides for a method comprising: receiving an analogue input signal and adding to the analogue input signal a feedback signal to generate a modified analogue signal. The method further includes passing the modified analogue signal through a high-pass filter and filtering out a portion of the analogue signal having a frequency below a chopping frequency, the chopping frequency being approximately half a sampling frequency, to produce a filtered analogue signal. The method further includes quantizing the filtered analogue signal at the sampling frequency to produce a digital signal, and converting the digital signal to an analogue signal to generate the feedback signal.

BRIEF DESCRIPTION OF THE DRAWINGS

For a more complete understanding of the present invention, and the advantages thereof, reference is now made to the following descriptions taken in conjunction with the accompanying drawings, in which:

FIG. 1 illustrates a delta modulator used in the continuous time converters CT according to the prior art;

FIG. 2 illustrates schematically an embodiment of a continuous time analogue/digital converter according to an embodiment of the invention;

FIGS. 3 and 4 illustrate schematically other embodiments of a continuous time analogue/digital converter; and

FIG. 5 illustrates schematically an example of a wireless communication device incorporating a continuous time converter.

DETAILED DESCRIPTION OF ILLUSTRATIVE EMBODIMENTS

Before addressing specific embodiments in detail, a brief overview of the various embodiments, and potential advantages thereof is provided. According to one embodiment, a system is proposed for converting analogue signals at the highest possible frequency that is not very costly and less complex than those described above.

Advantageously, a converter is proposed that can directly convert an analogue signal with the aid of a sigma delta modulator that is adapted without having to process the analogue input signal upstream of the modulator. Moreover, it may be advantageous to reduce the low-frequency noise associated with the processing of the analogue signal during its conversion to a digital signal. According to one aspect, a continuous time analogue/digital converter is proposed that comprises a sigma delta modulator configured to receive an analogue input signal. This modulator comprises high-pass filtering means the chopping frequency of which is equal to half of the sampling frequency of the quantization means of the said modulator. Therefore, the analogue input signal is converted directly at high frequencies, reducing the complexity of the converter.

Advantageously, no mixers are used for processing the input signal upstream of the modulator. By virtue of a high-pass filtering means, the bandwidth of the converter is increased for a given sampling frequency of the modulator. The sampling frequency of the sigma delta modulator may advantageously be approximately equal to twice the frequency of the analogue input signal. The high-pass filtering means may be produced with the aid of a simple high-pass filter or else from one or more resonators.

Therefore, according to one embodiment, the modulator comprises at least one summer, and the filtering means comprise at least one unit comprising a resonator and a variable-gain amplifier coupled between the output of the quantization means and an input of the at least one summer, the gain of the said variable-gain amplifier being fixed at a value for which the resonance frequency of the said resonator is equal to the said chopping frequency.

Therefore, by the use of a resonator, the accuracy of the filtering means is increased, that is to say that the low-frequency noise is more effectively pushed outside the payload frequency band of the analogue signal. It will be noted that this accuracy increases with the number of resonators used. The resonators make it possible to obtain a signal gain at the resonance frequency of the resonator which is higher than the gain of a conventional high-pass filter. Moreover, variable-gain amplifiers make it possible to adapt the sigma delta modulator according to the frequency of the input signal. According to another embodiment, the unit comprises at least one other variable-gain amplifier, the gains of all the amplifiers of the said unit being respectively fixed at values for which the resonance frequency of the said resonator is equal to the said chopping frequency. This improves the accuracy of each resonator. The modulator may also comprise a delay means coupled between the output of the quantization means and the input of one of the amplifiers of the said unit and configured to delay the digital output signal of the quantization means by a delay equal to half of the sampling period of the quantization means.

According to yet another embodiment, the filtering means comprise at least one other unit. The converter as defined above may be produced in integrated form within an integrated circuit. The various components of the converter may be produced in the form of specific logic or other circuits, or else in the form of software modules within a microprocessor. It will be noted here that the design of the high-pass filters on the integrated circuits, in particular in CMOS technology, is easier to achieve than for bandpass filters.

According to another aspect, a wireless communication device is proposed comprising a converter as defined above.

FIG. 2 shows schematically a continuous time analogue/digital converter according to one embodiment of the invention comprising a sigma delta modulator MSD1 in which the sampling frequency Fs of the quantization means QTZ is approximately equal to twice the frequency Fe of the analogue input signal x(t). Moreover, the sigma delta converter comprises a decimation filter, not shown for simplification purposes, coupled to the output of the quantization means QTZ. The modulator MSD1 comprises high-pass filtering means MF. These high-pass filtering means MF comprise in this instance a high-pass filter FPH the chopping frequency Fc of which is approximately equal to half the sampling frequency Fs of the quantization means QTZ. This high-pass filtering means also makes it possible to eliminate the low-frequency noise.

FIG. 3 illustrates schematically another embodiment of the continuous time analogue/digital converter. In this embodiment, the filtering means MF comprises a unit comprising a resonator RES, a first amplifier A1 with variable gain a1 and a second amplifier A2 with variable gain a2. This gives a high-pass filtering means of the second order, because the latter comprises a resonator RES with two variable parameters that are the variable gains a1, a2.

The modulator MSD1 of FIG. 3 comprises two channels V1, V2 in order to loop back the digital output signal y(n) to respectively two negative inputs of the summer SOM.

The first channel V1 comprises a first digital/analogue converter DAC1 coupled between the output of the quantization means QTZ and the first amplifier A1, the latter being coupled to the first negative input of the summer SOM.

The second channel V2 comprises a second digital/analogue converter DAC2 coupled between a delay means RT and the second amplifier A2, the latter being coupled to the second negative input of the summer SOM. The delay means RT is also coupled between the output of the quantization means QTZ and the second digital/analogue converter DAC2. This delay means RT makes it possible to delay the digital signal y(n) leaving the quantization means QTZ by a period equal to half the sampling period Ts of the modulator MSD1.

It will be noted that a resonator is a system which oscillates naturally at a precise frequency Fr which is its resonance frequency. The variable gains a1, a2 are determined as a function of the frequency Fe of the analogue input signal x(t) in order to obtain a resonance frequency Fr of the resonator that is approximately equal to half the sampling frequency Fs of the modulator MSD1.

It will also be noted that, for a conventional high-pass filter, the gain is usually between 20 and 30. On the other hand, for a resonator, the gain is between 300 and 400. Moreover, the resonators are precise and have a resonance difference of ±3 dB (decibels).

FIG. 4 illustrates a schematic representation of another embodiment of the continuous time analogue/digital converter. Certain elements described in the previous figures have also been transferred to this FIG. 4. In this other embodiment, the filtering means FPH comprise two units comprising respectively two resonators RES1, RES2 mounted in series in order to obtain a fourth-order high-pass filtering means. Each resonator is preceded by a summer SOM1, SOM2. The number of units, and in particular the number of resonators mounted in series, is not limiting and it is possible to produce filtering means which comprise more than two resonators in order to improve the precision of the filtering means MF. However, if the number of resonators is increased, the processing time is also increased for the conversion of the analogue signal x(t). This is why the use of two resonators provides a good compromise between precision and processing time for the digital conversion.

Moreover, the filtering means MF comprise, in a first unit, a first amplifier A1 with variable gain a1 and a second amplifier A2 with variable gain a2. These filtering means MF also comprise, in a second unit, a third amplifier A3 with variable gain a3 and a fourth amplifier A4 with variable gain a4.

As a non-limiting example, the continuous time analogue/digital converter may comprise a sigma delta modulator furnished with two resonators to convert an analogue input signal having a frequency Fe=2 GHz, with a sampling frequency Fs=4 GHz.

FIG. 5 shows schematically a wireless communication device APP. This wireless communication device APP comprises an antenna ANT for transmitting and receiving signals for communication with a remote base station. This device APP conventionally comprises a receive chain RXCH and a transmit chain, not shown here for simplification purposes.

The receive chain RXCH comprises an analogue portion comprising in particular a low noise amplifier LNA connected to a continuous time analogue/digital converter CCT which comprises a sigma delta modulator MSD1 as described above for converting the analogue input signal x(t) into a digital signal y(n) intended for a digital signal processor DSP.

Although the embodiments and their advantages have been described in detail, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the embodiments as defined by the appended claims. Moreover, the scope of the present application is not intended to be limited to the particular embodiments of the process, machine, manufacture, and composition of matter, means, methods and steps described in the specification. As one of ordinary skill in the art will readily appreciate from the disclosure, processes, machines, manufacture, compositions of matter, means, methods, or steps, presently existing or later to be developed, that perform substantially the same function or achieve substantially the same result as the corresponding embodiments described herein may be utilized according to the disclosure. Accordingly, the appended claims are intended to include within their scope such processes, machines, manufacture, compositions of matter, means, methods, or steps. In addition, each claim constitutes a separate embodiment, and the combination of various claims and embodiments are within the scope of the disclosure. 

What is claimed is:
 1. A sigma delta modulator comprising: a first summer configured to add an analogue input signal to a feedback signal to generate a modified analogue signal; a high-pass filter configured to filter the modified analogue signal to generate a filtered modified analogue signal; and a quantizer configured to sample the filtered modified analogue signal to generate a digital signal.
 2. The sigma delta modulator of claim 1 further comprising a digital to analogue converter configured to convert the digital signal to generate the feedback signal.
 3. The sigma delta modulator of claim 1, wherein the high-pass filter has a chopping frequency, and wherein the quantizer has sampling frequency, the chopping frequency being half of the sampling frequency.
 4. The sigma delta modulator of claim 3, wherein the sampling frequency is 4 GHz and the chopping frequency is 2 GHz.
 5. The sigma delta modulator of claim 1, wherein the high-pass filter comprises a first resonator.
 6. The sigma delta modulator of claim 5, wherein the high-pass filter further comprises an amplifier coupled between an output of the quantizer and an input of the first summer.
 7. The sigma delta modulator of claim 5, wherein the high-pass filter further comprises a second resonator.
 8. The sigma delta modulator of claim 1 further comprising a delay component coupled between an output of the quantizer and an input of the first summer.
 9. A wireless communication device comprising: a sigma delta modulator configured to receive an analogue input signal; a high-pass filter configured to filter the analogue input signal to generate a filtered analogue signal; and a quantizer configured to sample the filtered analogue signal to generate a digital signal.
 10. The wireless communication device of claim 9, wherein the high-pass filter has a chopping frequency, and wherein the quantizer has sampling frequency, the chopping frequency being less than the sampling frequency.
 11. The wireless communication device of claim 10, wherein the chopping frequency is equal to half of the sampling frequency.
 12. The wireless communication device of claim 9 further comprising: a low noise amplifier comprising an input coupled to an antenna and an output coupled to the sigma delta modulator; and a digital signal processor configured to receive the digital signal from the sigma delta modulator.
 13. The wireless communication device of claim 9 further comprising: at least one summer configured to add the analogue input signal to a feedback signal; and a digital to analogue converter configured to convert the digital signal to generate the feedback signal.
 14. The wireless communication device of claim 13 further comprising a delay component coupled between an output of the quantizer and an input of the at least one summer.
 15. The wireless communication device of claim 9, wherein the high-pass filter comprises at least one resonator and at least one variable-gain amplifier.
 16. The wireless communication device of claim 9, wherein the quantizer has a sampling frequency, the sampling frequency being equal to twice the frequency of the analogue input signal.
 17. A continuous time analogue/digital converter comprising: a sigma delta modulator configured to receive an analogue input signal; a quantizer having a sampling frequency; and a high-pass filter having a chopping frequency, the chopping frequency being equal to half of the sampling frequency.
 18. The continuous time analogue/digital converter of claim 17, wherein the sigma delta modulator further comprises at least one summer, and wherein the high-pass filter comprises at least one unit including a resonator and a variable-gain amplifier coupled between an output of the quantizer and an input of the at least one summer, the variable-gain amplifier having a gain set at a value wherein a resonance frequency of the resonator is equal to the chopping frequency.
 19. The continuous time analogue/digital converter of claim 18, wherein the high-pass filter comprises at least one other unit.
 20. The continuous time analogue/digital converter of claim 18, wherein the sigma delta modulator further comprises a delay component coupled between the output of the quantizer and the input of the variable-gain amplifier, the delay component being configured to delay a digital output signal of the quantizer by a period equal to half of the sampling period of the quantizer. 